A novel automatic underwater vehicle SOC estimator based on BPNN-AUKF at different temperatures

doi:10.19799/j.cnki.2095-4239.2024.0008

Abstract

Abstract:

This study proposes a state of charge (SOC) estimation method based on backpropagation neural network (BPNN) and adaptive unscented Kalman filter (AUKF). Firstly, a series of temperature compensation strategies were studied and designed to improve the estimation accuracy under low temperature and low SOC conditions, focusing on the relationship between battery SOC and terminal voltage at different temperatures. Secondly, a battery model coupled with temperature compensation strategy was established using backpropagation neural network (BPNN). This model can better adapt to battery state changes under low temperature and low SOC conditions, improving the accuracy of SOC estimation. Finally, a SOC estimation framework for BPNN-AUKF was established based on the BPNN battery model. By utilizing the information and residual sequences between measured and predicted values, the system process and measurement noise covariance were estimated and corrected. Through experimental verification, it was found that this method has significant advantages in low-temperature environments. Compared with traditional methods, it can more accurately estimate the SOC of batteries and has good generalization ability. This SOC estimator based on BPNN-AUKF method is not only suitable for autonomous unmanned underwater vehicles (AUV), but also has broad application value for other vehicles working in complex environments.

Key words: SOC estimation, adaptive unscented Kalman filter, temperature compensation strategy, neural network model, autonomous underwater vehicle

CLC Number:

TM 912

Qing LI, Shaowei ZHANG, Silun LUO, Juchen LI, Haichao CHENG, Chenyi LU. A novel automatic underwater vehicle SOC estimator based on BPNN-AUKF at different temperatures[J]. Energy Storage Science and Technology, 2024, 13(4): 1205-1215.

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References 14

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Temperature/℃	c_T
25	0
10	0.020
0	0.100
-10	0.180
-20	0.310

Methods	MAE	RMSE
BPNN	0.0160	0.0171
ECM_FFRLS	0.0185	0.0208
ECM_EKF	0.0194	0.0351

Methods	MAE	RMSE
BPNN-AUKF	0.0075	0.0270
ECM_FFRLS-UKF	0.0185	0.0443
ECM_EKF-UKF	0.0159	0.0432

Driving cycles	MAE	RMSE
UDDS	0.0064	0.012
LA92	0.0077	0.0179
HWFTE	0.0079	0.0191

Driving cycles	MAE	RMSE
UDDS	0.0160	0.0171
LA92	0.0165	0.0202
HWFTE	0.0056	0.0114